KR100701945B1 - Speed changeable Motor - Google Patents

Abstract

The present invention relates to a variable speed motor in which a single-phase AC power is input. In an external motor in which a single-phase AC power is input and a rotor is installed outside, the motor is wound on a stator to form six poles 1 and Sovereignty 2; In order to control the speed of the motor, the main winding 1 and the main winding 2 is configured to include a relay connected to any one of the series and parallel, respectively, because the speed of the motor can be adjusted without a drive driver device for variable speed from the outside Not only can the manufacturing cost of the variable motor be reduced, the electromagnetic vibration noise can be reduced, and the power consumption can be reduced.

Single-phase induction motor, external motor, winding, relay

Description

Speed changeable motor             

1 is an exploded perspective view showing a rotor and a stator of an abduction type motor.

Figure 2 is a winding arrangement of the motor showing the arrangement of a typical six-pole winding.

3 is a structural diagram of a pole number conversion single phase induction motor according to the related art.

4 is a circuit diagram illustrating a circuit in which a relay is connected between two windings of the main winding according to the present invention.

Figure 5a, b is a circuit diagram showing a parallel, parallel connection state of the winding form of the motor according to the present invention.

6 is a graph showing a change in the rotational speed of the motor according to the winding switching in accordance with the present invention.

7 is a circuit diagram showing a connection state of the windings of the forward and reverse rotation motors according to the second embodiment of the present invention.

<Explanation of symbols on main parts of the drawings>

10: Sovereign ship 1 20: Sovereign ship 2 30: Relay

The present invention relates to a variable speed motor, and more particularly, in an external motor in which a single-phase AC power is input and a rotor is installed outside, the motor windings 1 and 2 winding windings form six poles. And a relay configured to control a connection state such that the main winding 1 and the main winding 2 are connected in series or parallel, respectively, to adjust the speed of the motor. The present invention relates to a variable speed motor capable of varying properly.

In general, a motor is composed of a stator with a winding, a permanent magnet, and a rotor formed of an Al or iron core structure, and generates a periodic change of current in the winding recommended for the stator. The apparatus generates torque by generating torque in the rotor, and the motor is divided into an internal motor and an external motor according to the positions of the stator and the rotor.

In particular, the abduction type motor has a structure in which the stator is located inside the rotor and the external rotor rotates by a change in current flowing through the stator winding.

The abduction motor as described above has a larger radius of rotation compared to the civil motor in a structure in which the rotor is installed on the outside, so that the generation of torque per unit volume is increased, so that the use of a load with a large starting torque without the need for an expensive starting device is required. It can be used and has the advantage of being more compact in structure than a general electric motor in the case where the generation of the same torque is required.

In general, a single phase induction motor generates a counter electromotive force on the primary winding recommended on the stator side when a single phase AC voltage is applied, and also a counter electromotive force on the secondary winding recommended on the rotor conductor side by the magnetic field generated on the stator winding side. And torque is generated to rotate the rotor.

2 is a structural diagram showing a winding method of a general motor in which the stator windings form six poles, and two windings each form three poles on the stator, and recommend the opposite direction of the windings to form a single phase. When the alternating current power source E1 is applied, the direction of the currents for forming the adjacent poles is reversed, so that the polarities of the magnetic poles generated by the N poles and the S poles alternately appear.

However, in the case of applying single-phase AC power in the single-phase induction motor, only the alternating magnetic field whose size is changed in the direction of the winding axis is generated, so that no rotational force can be generated. The motor continues to rotate under the rotational force. Therefore, a starter is provided for the start-up, and is divided into a divided phase start type, a shading coil type, a condenser start type, a rebound start type, and the like according to the installed starter.

On the other hand, in the single-phase induction motor provided with the above starting device, the motor may require a high speed rotation or a low speed rotation due to the operating characteristics of the device to which the motor is mounted. However, when the motor is rotated by applying the single-phase AC power as described above, since the current change of the supplied power is kept constant, a separate device has to be provided for the variable speed of the motor. In general, an inverter circuit is added to a three-phase motor. Or a separate drive driver circuit is used, and in particular, the number conversion of a single-phase induction motor converting the number of poles of the motor to change the speed of the motor in order to lower the manufacturing cost of the variable speed motor will be described in detail with reference to FIG. 3.

3 is a view showing the structure of a conventional general pole-number conversion type single-phase induction motor, as shown in the two-pole main winding (1a, 1b), two-pole auxiliary winding (2a, 2b), 4 wound in the slot of the stator It consists of four windings, such as pole windings 3a, 3b, 3c and 3d, and four pole auxiliary windings 4a, 4b, 4c and 4d. The above-mentioned pole number conversion type single phase induction motor drives a motor by using a 2-pole main winding and a 2-pole auxiliary winding in 2-pole operation, and drives a motor by using 4-pole main winding and 4-pole auxiliary winding in 4-pole operation. have.

However, the above-described pole number conversion type single-phase induction motor of the prior art independently has high-speed and low-speed windings separately installed, and when the two poles or four poles are used separately, four windings are used for the pole number conversion. As the cross-sectional area of the slot increases, the efficiency of the motor decreases due to the increase of the iron loss of the stator, and the minimum variable speed that can be reached is limited, which makes it difficult to expand the variable speed range.

The present invention has been made to solve the above problems of the prior art, by adjusting the speed of the motor without a drive driver device for variable speed from the outside to reduce the manufacturing cost of the motor and reduce the electromagnetic vibration noise An object of the present invention is to provide a variable speed motor capable of reducing power consumption.

In the variable speed motor according to the present invention for solving the above problems, a single-phase AC power is input, the first main winding and the second main winding wound on the stator, a rotor installed and rotated outside the stator, and the And a relay connecting the first main winding and the second main winding to any one of a series and a parallel to adjust a speed of a rotor.
The variable speed motor according to the present invention can be used in a dish washing machine, a dish dryer, a washing machine, and the like.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

As shown in FIG. 4, in the abduction type motor in which the single-phase AC power source E1 is input and the rotor is installed outside, the motor includes a main winding 1 10 and a motor. The main windings 2 (20) are alternately formed on the stator, the N poles and the S poles are alternately formed to form six poles, and the relay 30 is added to adjust the speed of the motor. The connection state of the two (10, 20) is configured such that the serial or parallel connection can be switched between depending on the operating characteristics of the device on which the motor is mounted.

When the relay controls the connection state of the main windings 1, 2 (10, 20) so that the series or parallel connection is switched with each other, the voltage applied to each of the windings is changed, when the voltage of the applied AC power supply is 220V. When the windings are connected in parallel as shown in 5a, a voltage of 220 V is applied to the main windings 1 (10) and the main windings 2 (20), respectively. However, as shown in FIG. 5B, when the windings are connected in series, voltages are distributed to the respective poles, so that the voltages applied to the respective windings are 110V.

As such, the current flowing through each of the windings is changed due to the change of the connection state of the windings, and thus the induction current is generated in the rotor by changing the intensity of the magnetic field caused by the change of the current, and the induction current is rotated. Generates rotational torque for self rotation.

Since the rotation torque is proportional to the power applied to the motor, in the parallel connection, the motor is applied with a larger voltage than when the winding is connected in series, thereby generating a relatively large rotation torque, thereby increasing the rotation speed of the motor. On the contrary, the speed of the motor becomes slow in a series connection state in which a relatively small voltage is applied. Accordingly, by controlling the relay, the speed of the motor can be controlled by switching the connection state of the winding to the state required by the device handling the motor.

In the present invention, the means for converting the winding method of the motor into a series or parallel connection as described above is the circuit diagram shown in FIG.

In order to switch the series and parallel connection states of the two windings 10 and 20, the relay 30 changes the connection states of the nodes a, b, c, and d of the respective connection boards Box 1 and Box 2. To control, in order to rotate the motor at high speed by connecting the windings of the motor in parallel, the relay 30 connects the connection board inside the box1 to the node a and the node b, and the connection board inside the box2 connects to the node c. d controls the boxes 1 and 2 so that the nodes are connected. In addition, when the windings are connected in series to rotate the rotational speed of the motor at a low speed, the relay 30 controls the boxes 1 and 2 so that the a node of the box 1 and the d node of the box 2 are connected to each other in series and parallel to the windings of the motor. The state can be switched, and thus the rotational speed of the motor can be largely converted.

The relationship between the torque in each connection state of the winding, the motor speed, and the load is shown in the graph shown in FIG. 6.

When the windings are connected in parallel, the curve representing the relationship between the rotational speed and the torque of the motor is equal to the curve A. In this case, the curve A crosses the load curve at the n point. This means that when the motor is to be rotated at high speed, the torque required by the load is increased, and the motor can be rotated at a high speed while generating the torque while the windings are connected in parallel.

When the windings are connected in series in this manner, the relationship between the rotational speed and the torque of the motor is equal to the B curve. In this case, the B curve intersects the load curve at point m, which means to provide a constant torque to the load when the windings are connected in series, and to rotate the motor at a low speed. Therefore, by switching the connection state of the winding according to the speed required by the motor, it is possible to prevent problems such as the motor does not rotate properly, or wasted power consumption due to the over-torque more than the value required by the load.

The variable speed motor according to the present invention may be mounted in a washing machine that requires a shift according to a washing stroke. In the present invention, the motor mounted in the washing machine may be dehydrated at high speed when the washing machine is in a washing stroke. When the stroke is performed, the relay is switched so that the motor rotates at a low speed, so that the motor is shifted in each of the washing stroke and the dehydrating stroke.

Therefore, when the motor is mounted in the washing machine, the m point indicating the low speed rotation and low torque generation of the motor in the graph shown in FIG. 6 indicates that the motor is shifted for low speed dewatering during the dehydration operation in the washing machine. The speed and torque in the case of rotating to the motor, and the n point indicating the high speed rotation and high torque generation of the motor is the speed when the motor rotates at high speed and the motor rotates for high speed washing in the washing machine. Indicates torque.

Meanwhile, the auxiliary winding may be additionally mounted on the motor to allow the motor to rotate in reverse, which will be described in detail with reference to FIG. 7.

As shown in FIG. 7, the auxiliary windings 1 (11) and the auxiliary windings 2 (21) are mounted in the opposite direction to the main windings 10 and 20, and when the same AC power is applied thereto, the auxiliary windings 1 and 2 (11 and 21). ), Poles are created in the opposite direction, and the motor rotates in the reverse direction. In addition, the auxiliary windings 1, 2 (11, 21) are connected to the relay 31 so that the auxiliary windings 1, 2 (11, 21) are connected in series or parallel by the relay 31 as in the forward rotation of the motor. The connection is switched.

The switch SW1 may be used as a means for controlling the motor to make the motor rotate forward or reverse. As shown in FIG. 7, the switch SW1 may be connected to the u or v point. When the switch is connected to the u point and connected to the main windings 10 and 20, the motor rotates forward, and the switch SW1 is When the motor is connected to the v point and connected to the auxiliary windings 11 and 21, the motor reverses. Therefore, even when the motor rotates in reverse by the action of the switch means SW1 and the relay 31 as described above, the rotation speed can be largely converted.

Although the variable speed motor according to the present invention has been described with reference to the illustrated drawings, the present invention is not limited by the embodiments and drawings disclosed herein, and the motor is a washing machine, a dish washer, a dryer, or the like. It can be applied by those skilled in the art within the scope of the technical idea of.

The variable speed motor configured as described above uses a relay added to the winding so that the series and parallel connections of the winding are switched to each other to adjust the speed of the motor. The speed can be changed to reduce the manufacturing cost of the variable speed motor, and also to reduce the electromagnetic vibration noise by reducing the pore flux density, and to prevent the damage to the cloth and the power consumption when the motor is applied to the washing machine. It has an effect.

Claims (6)

In a variable speed motor in which a single phase AC power is input, A first main winding and a second main winding wound on the stator; A rotor installed outside the stator to rotate; And And a relay connecting the first main winding and the second main winding to any one of a series and a parallel to adjust the speed of the rotor. The method of claim 1, The relay may be configured to connect the first and second main windings in series to rotate the rotor at a first speed, and to connect the first and second main windings in parallel to make the rotor faster than the first speed. A variable speed motor, characterized by rotating at two speeds. A dish dryer comprising the variable speed motor according to claim 1. A dishwasher comprising the variable speed motor according to claim 1. Washing machine comprising a variable speed motor according to claim 1 or 2. delete

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